DOI: 10.17344/acsi.2014.583
Acta Chim. Slov. 2016, 63, 1-7
1
Scientific paper
Rapid and Sensitive Voltammetric Determination of Aclonifen in Water Samples
Dariusz Guziejewski,1* Sylwia Smarzewska,1 Monika Skowron,1 Witold Ciesielski,1 Agnieszka Nosal-Wiercinska2 and Slawomira Skrzypek1
1 Department of Inorganic and Analytical Chemistry, University of Lodz, Lodz, Poland
2 Department of Analytical Chemistry and Instrumental Analysis, Maria Curie-Sktodowska University, Lublin, Poland
* Corresponding author: E-mail: dguziejewski@uni.lodz.pl Tel.: +48(42)6355480; Fax: +48(42)6355808
Received: 01-05-2014
Abstract
This paper presents the use of square wave voltammetry (SWV) and square wave adsorptive stripping voltammetry (SWAdSV) in conjunction with a cyclic renewable silver amalgam film electrode (Hg(Ag)FE) for the determination of aclonifen in spiked water samples. A reduction peak at -0.65 V versus Ag/AgCl was obtained in the selected buffer (borax buffer with pH 9.2), exhibiting the characteristics of an irreversible reaction. The effect of square wave (SW) frequency, SW amplitude and step potential, as well as accumulation parameters (time and potential) were studied to select the optimal experimental conditions. The calibration curve was linear in the aclonifen concentration range from 1.0 x 10-7 to 1.0 x 10-6 mol L-1 and from 1.0 x 10-8 to 1.0 x 10-7 mol L-1 for SWV and SWAdSV, respectively. The detection and quantification limits were found to be 3.1 x 10-8 mol L-1; 1.0 x 10-7 mol L-1 and 2.9 x 10-9 mol L-1; 9.6 x 10-9 mol L-1 for SWV and SWAdSV, respectively. The proposed method was applied successfully in the determination of aclonifen in spiked water samples. The developed procedure can be adequate at least for screening purposes, where positive results should be confirmed by more selective method.
Keywords: Aclonifen determination; silver amalgam film electrode; square wave voltammetry; herbicide
1. Introduction
Herbicides are used globally to eliminate weeds. Even after one application, they can be absorbed by the plant or deposited on the soil surface. These processes are strongly dependent on the type of herbicide, crop, soil, application method, and climatic conditions. Thus, nowadays, there is a growing emphasis on the development of analytical methods for determination of herbicides due to their toxicity.1,2
Aclonifen (Scheme 1) is a diphenylether herbicide used in the preemergence control of broad-leaved and grass weeds in sunflower cultivation around the world.3,4
CI
Scheme 1. Chemical structure of aclonifen (2-chloro-6-ni-tro-3-phenoxyaniline).
The mode of action is based on inhibition of chlorophyll5,6 and carotenoid synthesis7 causing large foliar necroses.8 Aclonifen is a moderately hazardous herbicide. Pursuant to the directive of the European Union Commission from
15.12.2008,	aclonifen was approved for use since
08.01.2009.	Higher concentrations may cause skin irritation or renal and hepatic function disorders after prolonged exposure. The use of this particular herbicide entails a huge risk for aquatic organisms as well.9 As aclonifen is stable in aqueous media and soil, the likelihood of accumulation is very high. Degradation time varies from 15.4 to 16.1 days,10 but an exposure of only 96 h is sufficient to curb the growth of algae and cause fish death.9
Aclonifen is usually analyzed with gas11 or liquid chromatography,12 often in combination with mass spec-trometry.13 Several electrochemical14-16 methods have been developed for herbicide determination. Zaouak and coworkers14 as well as Inam and Cakmak15 investigated ac-lonifen electrochemical oxidation processes and its determination on a glassy carbon electrode. Achieved limits of
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detection were only 0.6 and 0.07 mg L-1, respectively, while Novotny and Barek used differential pulse voltammetry and reduction peak with detection limit 2 pmol L-1.16
While the methods based on high performance liquid chromatography and/or spectrometry are obviously both sensitive and selective, they are also financially and instrumentally demanding and rather time consuming. On the other hand, modern voltammetric techniques are inexpensive, sensitive, and fast, and thus applicable for wide-scale monitoring of electrochemically active pollutants. Although a mercury electrode is clearly the best choice for electroanalytical determination of aclonifen, there is a tendency to replace liquid mercury electrodes with other non-toxic materials, e.g., bismuth or solid amalgam electrodes, due to strict safety and ecological rules. An example of such an electrode is a renewable silver amalgam film electrode (Hg(Ag)FE),17-20 which properties, such as a wide potential window, easily mechanically renewable surface, and low noise, make it a very promising electroanalytical tool. Liquid amalgam, with a volume not exceeding 10 pL, enables stable electrode functioning for several months. A Hg(Ag)FE has been successfully applied in quantitative analysis of various elements and organic compounds.21-24 This paper presents mechanistic studies and quantitative determination of aclonifen.
2. Materials and Methods
2. 1. General Voltammetric Procedure, Instrumentation and Software
All voltammetric experiments were carried out using a nAutolab Type III (Eco Chemie, Netherlands) with GPES software (General Purpose Electrochemical System, version 4.9). A classical three-electrode system consisting of a reference electrode (Ag/AgCl - 3 mol L-1 KCl), a counter electrode (Pt wire), and a working electrode (a renewable silver amalgam film electrode from mtm-anko, Cracow, Poland) was used. The construction details and properties of the Hg(Ag)FE have been described previously.17
Quantitative measurements were performed using SWV or SWAdSV and the standard addition procedure. The reported signals are based on peak currents measured after subtraction of the blank. The amalgam film of the Hg(Ag)FE electrode was refreshed before each measurement. A potential of -0.9 V was applied to condition the electrode after the refreshing step. In SWAdSV experiments, during the accumulation step, a potential of -0.2 V was applied with the solution being stirred. After the accumulation period, the solution was equilibrated for 5 s. Subsequently, a voltammogram for the blank was recorded, and the required volumes of the compound were added. Measurements were carried out in deaerated solutions. The optimal results for SW experiments were obtai-
ned in borax buffer at pH 9.2, SW amplitude Esw = 50 mV, step potential AE = 5 mV, frequency f = 150 Hz. For ad-sorptive stripping voltammetry measurements accumulation time t = 45 s, and accumulation potential E =
acc	'	•*•	acc
-0.2 V were selected. All electrochemical measurements were carried out at the ambient temperature of the laboratory.
Spiked water solutions were prepared as follows: 1 mL of 1.0 x 10-5 mol L-1 aclonifen solution was transferred to a 25 mL flask and filled to volume with tap or river water. In voltammetric experiments, the supporting electrolyte contained 1 mL of (spiked tap/river) water solution and 9 mL of borax buffer with pH 9.2. The acloni-fen concentration in spiked samples was analyzed using the standard addition method. Each addition contained 0.4 nmol of herbicide. Voltammograms were recorded after each addition. Recoveries were calculated after six replicate experiments.
2. 2. Solutions and Materials
An aclonifen standard was purchased from Dr Ehrenstorfer (Augsburg, Germany). The supporting electrolytes were 0.04 M Britton-Robinson (BR), 0.2 M borax, and 0.2 M borate buffers. All the chemicals used for the preparation of buffer solutions were from POCH S.A. (Gliwice, Poland). Fresh stock solution (1.00 x 10-3 mol L-1) was prepared weekly by dissolving 6.62 mg of aclo-nifen in 5 mL of ethanol (storage in dark and cool place if not in use). This concentrated solution was transferred to a 25 mL flask and filled to volume with water which had been demineralized in a PURALAB UHQ (Elga LabWa-ter, UK).
3. Results and Discussion
3. 1. Electrochemical Behavior of Aclonifen and the Influence of pH and SW Parameters
Generally, pH is one of the factors that strongly influence the shape of recorded voltammograms, and it is important to test the effect of supporting electrolyte pH on electrochemical systems. The impact of the medium was evaluated using 0.04 mol L-1 Britton-Robinson buffers (pH 2.0-10.0) with 5 x 10-7 mol L-1 aclonifen solution. Fig. 1 illustrates the influence of BR buffer pH on aclonifen peak current Ip and potential Ep. With increasing pH, the acloni-fen signal rises and shifts towards more negative potentials. As it can be seen from the inset in Figure 1, the plot of Ep versus pH is linear across the entire examined range.
The slope of the plot (0.059 V) is identical to the theoretical value, so it can be assumed that the examined signal indicates a process in which equal numbers of protons and electrons are involved (the slope of the same re-
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Figure 1. Voltammograms of 5 X 10 7 mol L 1 aclonifen solution recorded in BR buffers with the following experimental conditions: SW amplitude Esw = 25 mV, AE = 5 mV, f = 50 Hz; Inset: relationship between pH and aclonifen peak potential.
lationship obtained for the second signal was equal to 0.06 V). As the highest aclonifen signals were observed in an alkaline medium, other supporting electrolytes were also examined (borax and borate buffers). Finally, borax buffer with pH 9.2 was chosen for further studies due to the best
peak shape and maximum current value. The influence of the ionic strength of the supporting electrolyte was also examined. The ionic strength was varied with changing borax buffer content (from 5 to 100%, % v) in the supporting electrolyte. On the basis of these results, the supporting electrolyte chosen for further studies contained 50% borax buffer and 50% water.
Two reduction peaks are visible in Figure 2, which presents preliminary cyclic voltammetric experiments carried out with a Hg(Ag)FE in 1 x 10-5 mol L-1 aclonifen solution in borax buffer (pH 9.2) at several scan rates. In the reverse potential sweep there was no trace of an anodic process, which demonstrated the irreversibility of electrode reactions. To explain the nature of this process, the influence of the scan rate (v) on the better defined peak current (at Ep = -0.65 V) was investigated. The relationship between the peak current and the scan rate was linear and can be illustrated with the equation I = kvx (k-constant parameter). The values of x were expected to be 0.5 and 1 for diffusion-controlled and adsorption-controlled reactions,25,26 respectively. The regression of log(Ip) vs. log(v) gave a slope value of 0.96 (the correlation coefficient of the straight line is 0.9936), indicating that the reduction current is controlled with adsorption.
Such an electrode mechanism can be described by two equations:
Ox ^ Ox,„
OXads + ne ^ Redads
(1) (2)
Figure 2. Cyclic voltammograms for 1 x 10 5 mol L 1 aclonifen solution in borax buffer (pH 9.2) at various scan rates: (a) 30, (b) 50, (c) 75, (d) 100, (e) 200, (f) 300, (g) 500, and (h) 700 mV s-1; inset: the linear relationship between the log peak current Ip and log scan rate v for the first peak (Ep = -0.65 V).
In 1988, Lovric et at.21 evaluated empirical expression resulting from the reactions above: Peak position:
EP- E0-
: (RT -
anF)ln (k0tp) - 0.7AE
(3)
The electrochemical signal of aclonifen was tested with various voltammetric techniques, such as cyclic vol-tammetry, linear sweep voltammetry, differential pulse voltammetry and square wave voltammetry. Thanks to the highest peak currents, the best sensitivity, and the possibility to carry out experiments at high scan rates over short analysis time, square wave voltammetry was chosen for further analytical application. In an alkaline medium, the SWV response of aclonifen (Fig. 1) exhibits two peaks at approximately -0.65 V (peak 1) and at -1.15 V (peak 2, not shown) as in cyclic voltammetry measurements - Fig. 2. The voltammograms recorded with SWV confirm the irreversibility of the reduction reaction.
In such a case, two possible reduction pathways of the nitro group present in the aclonifen molecule should be considered.28-31 In the first pathway (Equation (4) and (5)), reversible formation of one-electron nitro radical anion is followed by irreversible three-electron reduction. As the stability of ArNO2 is increased by the absence of
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free protons, this mechanism is the most common in apro-tic solvents or strongly alkaline aqueous media.
ArNO; + 3e~ + AH+ ArNHOH + Hfi	(5)
In the second possible pathway (Equation (6) and (7)), four-electron reduction of NO2 to NHOH (Equation (6)) and two-electron reduction of NHOH to NH2 (Equation (7)) takes place. This mechanism occurs in acidic and slightly alkaline aqueous media.
ArNO,+4e~ + 4H+ -> ArNHOH + H20	(6)
ArNHOH + 2e~ + 2H* -» ArNH1 + H20	(7)
Considering the above, it can be assumed that the voltammetric response obtained at the Hg(Ag)FE in the presence of aclonifen is the result of nitro group reduction consistent with the second presented mechanism. This is confirmed by several factors: irreversibility of the signals (both peaks),30,32 an equal number of electrons and protons involved (both peaks), and shifting of the first signal to more negative potentials with increasing pH.29,33 Based on these results, we suggest the following electrode reaction pathway: the peak located at -0.65 V represents the reduction of the nitro group to hydroxylamine, and the second signal at -1.15 V is related to the reduction of hydroxylamine to amine (Scheme 2).
the peak current was attained up to ESW = 50 mV, which then stabilized, according to theory.27 SW amplitude values higher than 50 mV did not improve the sensitivity of the technique.
■0.40 ■0.45		y=0,752x-0.630 RJ=0.9949	— — 5mV ----20 mV ---40 mV
— -0.50 S ^-0.55		/	-----70 mV ----90 mV .......125 mV .........150 mV
-0.60		/	-200 mV i
-0.65			/:
	0 0.1 0.2 fswM		/ * r / * f
		ray. A ( I V * / Vivv-f	/''/ '' / / I ' ' /// /.' y /
			
-0.40 -0.55 -0.70 -0.85 -1.00
Em
Figure 3. Effect of varying the SW amplitude on the shape and position of voltammograms obtained for 1 X 10-7mol L-1 acloni-fen solution in borax buffer (pH = 9.2), f = 25 Hz, AE = 5 mV; inset: variation of the peak potential as a function of the SW amplitude.
OH
Scheme 2. Electrochemical reduction of aclonifen.
Experimental SWV parameters for the voltammetric determination of aclonifen were estimated in order to identify the conditions at which the observed maximum peak height is accompanied by the best signal shape. This optimization was performed by varying the SW frequency f), the height of SW pulses (SW amplitude, ESW), and the step potential of the staircase waveform (AE) for SWV, and additionally the accumulation time and potential for SWAdSV. While adjusting SW parameters, each of them was changed with the others kept constant using 1 x 10-7 mol L-1 aclonifen concentration. First, the SW amplitude was varied between 5 and 200 mV. A linear response of
Furthermore, with increasing SW amplitude, the value of the peak potential shifts towards less negative values. This behavior may provide an invaluable advantage in determining aclonifen in complex matrixes. In addition, the plot Ep = f(Esw) has a slope of 0.752 (Figure 3), which is similar to the value of 0.7 predicted by Equation (3).27 Changes in frequency (8-1000 Hz) influence the peak current, which is linear in the range of 8-250 Hz. In further work, 150 Hz was applied. Although the use of a higher f would have given a higher response, we decided against it because of the growing capacitive current and an uncompensated ohmic drop effect.34 The step potential was investigated in the range of 1-21 mV. The best response was obtained for 5 mV, while higher values of AE led to a poorly shaped aclonifen signal. The adsorptive properties of aclonifen at alkaline pH make it possible to accumulate it on the Hg(Ag)FE in a step preceding its voltammetric determination. To improve the sensitivity of the SWAdSV method, the influence of accumulation potential (Eacc) and accumulation time (tacc) was studied for an aclonifen concentration of 1 x 10-7 mol L-1. The effect of the accumulation potential on the stripping peak current was examined over the range -0.5 V to 0.0 V. The maximum peak current was registered for aclonifen at
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E,_„„ = -0.2 V. Then, the effect of i on the aclonifen peak
acc	'	acc
height was checked. The optimum accumulation time to the electrode surface saturation was 45 s. A further increase of tacc caused a significant drop in the voltamme-tric response of aclonifen. Such behavior suggests a high affinity of aclonifen molecules to the electrode surface and interaction between adsorbed molecules as well. For subsequent studies, an accumulation time of 45 s was chosen.
Figure 4. SW voltammograms of aclonifen in borax buffer with pH 9.2, herbicide concentrations: (a) 0.1, (b) 0.2, (c) 0.4, (d) 0.6, (e) 0.8, (f) 1.0 |imol L-1 (SWV); (a) 0.01, (b) 0.02, (c) 0.04, (d) 0.06, (e) 0.08, (f) 0.10 iimol L-1 (SWAdSV). The other experimental conditions were: SW amplitude Esw = 50 mV, step potential AE = 5 mV, and frequency f = 150 Hz; and additionally, for SWAdSV, tacc =
3. 2. Analytical Application
Quantitative measurements were performed using square wave voltammetry (SWV) and square wave ad-sorptive stripping voltammetry (SWAdSV). Due to the larger current value and a better shape, the peak at -0.65 V was chosen for analytical purposes (Figure 2). The applicability of SWV and SWAdSV for the determination of aclonifen was examined as a function of its concentration in the range 1 x 10-7-1 x 10-6 mol L-1 and 1 x 10-8-1 x 10-7 mol L-1, respectively (Figure 4). Above those ranges, the decline of linearity was probably caused by aclonifen
12.0
10.0
8.0
6.0
4.0
2.0
0.0
Tap	
water	
	2
	1
	1 s
	
12.0
10.0
8.0
6.0
4,0
2.0
0.0
River	3
water	
	2
	1 1
	1 s
-0.4 -0.6 -0.8 £[V]
-0.4 -0.6 -0.8 H [VI
Figure 5. Voltammograms of aclonifen determination in spiked river samples using the standard addition method (s - sample; 1, 2, 3 - standard additions). Experimental conditions are the same as in Fig. 4.
45 s and E = -0.2 V.
acc
Table 1. Recovery and precision of the aclonifen peak currents at various aclonifen concentrations.
Added |>mol L1]	Found [^mol L 1] (n = 6)	Confidence interval3 [^mol L 1]	Precision RSD [%]	Recoveryb [%]
SWV				
0.10	0.11	0.004	4.1	113
0.20	0.20	0.009	5.6	99.6
0.40	0.40	0.02	7.2	100
0.60	0.57	0.02	5.6	94.4
0.80	0.81	0.03	4.8	101
1.00	1.01	0.03	3.4	101
SWAdSV				
0.0100	0.0098	0.0001	1.4	98.0
0.020	0.020	0.0009	6.0	99.5
0.040	0.042	0.001	3.1	105
0.060	0.056	0.002	4.7	94.0
0.080	0.080	0.002	2.3	99.8
0.100	0.097	0.003	4.6	96.9
Note: a t(S/n1/2), p = 95%, n = 6; b Recovery = 100 % + [(Found - Added) / Added] X 100 %
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saturation on the electrode surface. The cathodic peak current increased linearly with increasing concentration of aclonifen and is expressed by the equations Ip (A) = 1.5 x 10-7 (A) + 5.3 (A L mol1) x c(analyte, mol L-1) (correlation coefficient 0.9975) and Ip (A) = 6.1 x 10-9 (A) + 57.0 (A L mol-1) x c(analyte, mol L1) (correlation coefficient 0.9956) for SWV and SWAdSV, respectively.
The limits of detection (LOD, 3.1 x 10-8 and 2.9 x 10-9 mol L-1) and the limits of quantification (LOQ, 1.0 x 10-7 and 9.6 x 10-9 mol L-1) of aclonifen, for SWV and SWAdSV, respectively were calculated as in the work of dos Santos and coworkers.35 The one-day repeatability of the developed method was tested with six replicate measurements for each studied aclonifen concentration. In order to check the correctness of the method, precision (RSD) and recovery were also calculated for different analyte concentrations in the linear range (Table 1).
3. 3. Analysis of Aclonifen in Spiked Environmental Samples
The developed procedure was applied for analysis of tap and river water using standard addition method. There was no need for any evaporation, precipitation, or extraction steps prior to the herbicide assay and details are given in Section 2.3. Voltammograms obtained during the experiments are shown in Figure 5. No additional peaks were observed within the examined potential window in the studied water samples. Analyte recovery results calculated from the linear regression equations are given in Table 2. Elaborated voltammetric method of aclonifen determination can be applied for screening purposes in such environmental samples. Due to lack of general selectivity the method is not advised when more complex matrices are met.
Table 2. Quantitative assay results from aclonifen spiked water and mean recovery values.
	Tap water	River water (Bzura)
Concentration added [pmol L-1]	0.400	0.400
Concentration found [pmol L-1]	0.408	0.403
Correlation coefficient	0.9997	1.000
Precision (RSD) [%]	3.7	3.7
Recovery [%]	102.5	102.9
3. 4. Interferences
The selectivity of the proposed method was evaluated by the addition of possible interferents, such as heavy metal cations (divalent Cd, Zn, Pb and Cu) and organic compounds acting as antibodies, fungicides, and insecticides (blasticidin S, nitrothal, acibenzolar S and clothianidin). The concentration of each interferent was increased as follows: 0.01, 0.05, 0.1, 0.25, 0.5 and 1.0
( x 10-6) mol L-1. The response was compared with the result obtained for pure aclonifen solution (1 x 10-7 mol L-1). The presence of zinc, lead and cuprum ions as well as blasticidin S and clothianidin didn't interfere with analyte voltammetric response. Cadmium ions and nitrothal precluded aclonifen determination if the ratio ac-lonifen/interferent was above 1:3. The presence of aci-benzolar S rules out the aclonifen determination. These results suggest that although method is not selective, it can be used for screening purposes in rather simple environmental samples.
4. Conclusion
We have demonstrated that the tested herbicide is an electrochemically active compound at a renewable silver amalgam film electrode. The electrode process consists of irreversible reduction of aclonifen and is adsorption-controlled. The voltammograms consisted of two cathodic signals associated with the reduction of the nitro group and were recorded in the alkaline medium of borax buffer with pH 9.2.
The developed electroanalytical procedure enabled aclonifen determination in the concentration range of 1 x 10-7-1 x 10-6 mol L-1 and 1 x 10-8-1 x 10-7 mol L-1 using square wave voltammetry and square wave adsorptive stripping voltammetry, respectively. The method was also applied successfully in the determination of aclonifen in spiked tap and river water samples. The presented voltam-metric method of aclonifen determination can be considered as a sensitive and effective. It can serve as an alternative to expensive chromatographic methods for routine analysis of environmental samples at least for screening purposes. Moreover, despite its limited selectivity the Hg(Ag)FE can be directly applied for field analysis of environmental samples due to its mechanical stability and easy film regeneration in contrast to the classical hanging mercury drop electrode.
5. Acknowledgements
This work was supported by the University of Lodz, Poland under Grant for young investigators No. 545/338 and 545/726.
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Povzetek
V članku je predstavljena uporaba voltametrije s kvadratnim spreminjanjem potenciala (»square wave voltammetry«, SWV) in »square wave« adsorptivne inverzne voltametrije (»square wave adsorptive stripping voltammetry«, SWAdSV) v povezavi s ciklično obnovljivo Hg (Ag) FE elektrodo za določanje aklonifena v obogatenih vodnih vzorcih. Izbor optimalnih eksperimentalnih pogojev je bil narejen na osnovi proučevanja vpliva frekvence SW, amplitude SW, časa in potenciala.
Umeritvena krivulja za aklonifen je linearna v koncentracijskem območju od 1,0 x 10-7 do 1,0 x 10-6 mol L-1 za SWV in od 1,0 x 10-8 do 1.0 x 10-7 mol L-1 za SWAdSV. Za SWV je meja zaznave 3,1 x 10-8 mol L-1, meja določitve pa 1,0 x 10-7 mol L-1, za SWAdSV pa je meja zaznave 2,9 x 10-9 mol L-1, meja določitve pa 9,6 x 10-9 mol L 1. Predlagana metoda je bila uspešno uporabljena za določanje aklonifena v obogatenih vodnih vzorcih in je primerna za presejalne analize, vendar je potrebno pozitivne rezultate preveriti še z bolj selektivno metodo.
Guziejewski et al.: Rapid and Sensitive Voltammetric Determination